DE102019100653A1 - Bipolar electrosurgical instruments - Google Patents

Abstract

A bipolar surgical instrument (1) comprises a trunk (2), first and second jaws (18, 20) opposing each other and located at the distal end of a shaft (10), the first jaw (18) in Reference to the second jaw (20) between an open position in which the first and second jaws (18, 20) are spaced apart from each other and a closed position in which the first and second jaws (18, 20) are adjacent one another are movable. The first and second elongated jaw members (18, 20) have a first and a second electrode corresponding thereto. A power cable having a pair of electrically conductive elements is adapted to connect a source of radio frequency based electromagnetic energy to the first and second electrodes. A capacitive element is located in the instrument and is connected in series between a first of the pair of electrically conductive elements of the cable and the first electrode.

Description

The present invention relates to bipolar electrosurgical instruments.

Bipolar surgical instruments are used to pinch and seal tissue, such as blood vessels, during a surgical procedure. The clamping is usually carried out by means of a pair of opposing jaws, which are remote-controlled so that thereby a vessel to be sealed is clamped. Sealing is typically accomplished by the use of high frequency electrical energy supplied to the tissue to be sealed via the electrodes attached to the opposing jaws of the instrument.

Existing types of such instruments may not provide optimal transmission of electrical energy to the tissue and may not provide optimal tissue integrity. It is therefore desirable to provide an improved bipolar surgical instrument that makes it possible to at least partially overcome these disadvantages.

Aspects of the invention are set forth in the appended claims.

According to an exemplary aspect, there is provided a bipolar electrosurgical instrument comprising: a trunk; an elongate shaft attached to the trunk, the elongate shaft extending toward a distal end; first and second elongated jaw members located at the distal end of the elongate shaft and supporting first and second electrodes, respectively, the jaw members being relatively spaced from one another in an open position in which the first and second electrodes are spaced from one another; and a closed position in which the first electrode is located adjacent to the second electrode, are movable; a power cable having a pair of electrically conductive elements and a first end to which it is connected to a source of high frequency electromagnetic energy and a second end to which it is connected to the first and second electrodes; and a first capacitive element located in the instrument and connected in series between a first one of the pair of electrically conductive elements of the cable and the first electrode.

An example further includes a second capacitive element located in the instrument and connected in series between a second of the pair of electrically conductive elements of the cable and the second electrode.

In one example, the first electrode is an active electrode and the second electrode is a counter electrode. In an alternative example, the first electrode is a counter electrode and the second electrode is an active electrode.

The or each capacitive element may be a capacitor.

An example further includes a control cable including at least one control conductor for providing a control signal path. An example further comprises a measuring cable, which comprises at least one measuring conductor for providing a measuring signal path.

According to another exemplary aspect, there is provided an electrosurgical system comprising a bipolar electrosurgical instrument according to the first exemplary aspect, and a waveform generator connected to the power cord of the instrument for providing high frequency signals to the first and second electrodes via the power cable.

• 1 und 2 zeigen Seitenansichten eines bipolaren chirurgischen Instruments, die jeweils einen Aspekt der vorliegenden Erfindung in einer offenen bzw. einer geschlossenen Stellung verkörpern;
• 3 veranschaulicht einen Controller zur Verwendung mit einem bipolaren chirurgischen Instrument;
• 4 veranschaulicht ein elektrisches Modell eines bipolaren chirurgischen Instruments; und
• 5 veranschaulicht ein elektrisches Modell eines bipolaren chirurgischen Instruments, welches die vorliegende Erfindung verkörpert.

In one example, the waveform generator includes a high frequency signal generator for providing a high frequency signal to the first and second electrodes via the power cable and a controller for controlling the operation of the high frequency signal generator in response to a received control input.

• 1 and 2 10 show side views of a bipolar surgical instrument, each embodying an aspect of the present invention in an open position and a closed position, respectively;
• 3 illustrates a controller for use with a bipolar surgical instrument;
• 4 illustrates an electrical model of a bipolar surgical instrument; and
• 5 FIG. 12 illustrates an electrical model of a bipolar surgical instrument embodying the present invention. FIG.

An example of a bipolar surgical instrument 1 is schematic in 1 and 2 shown. 1 illustrates an open position of the instrument 1 and 2 illustrates a closed position thereof.

The instrument 1 includes a hull 2 with a main body 4 from which a festival hold 6 extends. At the festival hold 6 becomes the instrument 1 while using the Operator held. A movable operating handle 8th is movable on the main body 4 of the hull 2 assembled. An elongated shaft 10 is on the main body 4 of the hull 2 attached and extends from a proximal end 12 on the main body 4 to a distal end 14 of the shaft 10 , The shaft 10 defines along this a longitudinal axis and an elongated passage extending from the proximal end 12 to the distal end 14 of the shaft 10 ,

A few 16 opposing jaws located at the distal end 14 of the shaft 10 , The baking pair 16 includes a first jaw 18 and a second cheek 20 , In the example off 1 and 2 are the first and the second cheek 18 and 20 pivoted on a Backendrehgelenkt 22 assembled. The first and the second cheek 18 and 20 are around the jaw swivel 22 around between an open position (in 1 shown), in which the jaws 18 and 20 are separated from each other, and a closed position (in 2 shown), in which the jaws 18 and 20 are adjacent to each other, pivotable. In another example of a bipolar instrument embodying the present invention, only one of the jaws is movable. In another example, the movable jaw or jaws may be movable in any suitable manner, such as linearly or in a combination of rotational and linear motion. The exact nature of the movement of the jaws is irrelevant in the context of the present invention.

The first and the second cheek 18 and 20 each carry the first and second electrodes 19 and 21 , The first and second electrodes 19 and 21 are designed to deliver high-frequency electromagnetic energy between the first and second jaws 18 and 20 apply retained tissues.

In use, an operator moves the instrument 1 the operating handle 8th from a first position (in 1 shown) in a second position (in 2 shown) to the cheeks 18 and 20 to move from the open position to the closed position. During such a process, the tissue to be sealed will be between the closed jaws for a predetermined period of time 18 and 20 while pressure is applied by the operator and high frequency energy is applied to the tissue. The high-frequency energy serves to seal the retained tissue.

3 illustrates this with a waveform generator 30 connected instrument 1 , The waveform generator 30 receives an electrical power supply 32 and includes a controller 34 and a high frequency signal generator 36 , A control cable 38 connects the controller 34 with control inputs, which in an example in or on the instrument 1 are located. The control inputs can also be connected to one of the instrument 1 be located separate place and be formed for example in the form of a footswitch. In addition, a measurement cable may be provided to provide a path for measurement signals.

The controller 34 serves to the signal generator 36 to control which by a power cable 40 with the instrument 1 connected is. The power cable 40 includes a pair of conductors, each with corresponding electrodes 19 or. 21 of the instrument 1 are connected. Upon receipt of an appropriate control signal, the controller initiates 34 the signal generator 36 about it, over the power cable 40 a high frequency electrical output signal to the first and second electrodes 19 and 21 provide. One of the electrodes is defined as the active electrode and one as the counter electrode.

The output high frequency electrical signal may have any suitable features, such as voltage, current and frequency, and may be generated to provide a desired sealing waveform on that between the first and second jaws 18 and 20 apply retained tissues.

4 illustrates an electrical model 50 a previously discussed instrument including connected signal generator according to 3 , The connected signal generator 52 serves to send high-frequency signals to the first and second electrodes via the power cable 62 and 64 of the instrument. The power cable has electrical characteristics caused by the resistance 54 , the capacity 56 and the inductance 58 are shown. The tissue to be sealed has an impedance and this is in 4 through the element 60 shown.

It will be readily appreciated that the electrical characteristics of the system are largely dependent upon the frequency of the radio frequency signal provided by the signal generator and the impedance of the tissue to be sealed. In the case of a high-frequency signal with suitable frequencies, in order to achieve the required sealing, the inductance 58 lead to a considerable voltage drop across the length of the cable. This voltage drop causes the over the first and second electrodes 19 and 21 applied voltage is considerably reduced, which is associated with insufficient energy transfer to the tissue to be sealed. This becomes particularly noticeable in the case of a low tissue impedance, for example in the range of 50 ohms.

wobei C für die Kapazität, Fr für die Betriebsfrequenz des Systems und L für die Kabelinduktivität 78 steht. 5 illustrates an electrical model 70 an instrument including a signal generator embodying an aspect of the present invention and as shown in FIG 3 connected. The connected signal generator 72 serves to send high-frequency signals to the first and second electrodes via the power cable 82 and 84 of the instrument. Again, the power cord on electrical characteristics that caused by the resistance 74 , the capacity 76 and the inductance 78 are shown. The tissue to be sealed has an impedance, and this is in 5 through the element 80 shown. According to the basic principles of the present invention is a capacitive element 86 For example, a capacitor between a first of the pair of electrically conductive elements of the cable and the first electrode 19 connected in series. The capacitive element 86 is inside the instrument 1 either in the trunk of the instrument 1 or in its elongated shaft 10 , The capacitance value of the capacitive element 86 is chosen to match the cable inductance 78 at the signal frequency appropriate for use with low impedance loads. The capacitance value of the capacitive element 86 can be calculated according to the following formula: $$C=\frac{1}{{\left(2\pi F_r\right)}^2\times L}$$

where C is the capacitance, Fr is the operating frequency of the system, and L is the cable inductance 78 stands.

The capacitive element 86 may be connected in series between any one of the pair of electrically conductive elements of the cable and any one of the first and second electrodes. Alternatively, the capacitive element 86 also be provided by two elements, one connected in series between a first of the pair of electrically conductive elements of the cable and the first electrode, and an element connected in series between the other of the pair of electrically conductive elements of the cable and the second electrode ,

In this way, one embodiment of the present invention can provide improved sealing features for a bipolar electro-surgical instrument.

Claims (9)

Bipolar electrosurgical instrument comprising: a hull; an elongate shaft attached to the trunk, the elongated shaft extending toward a distal end; first and second elongated jaw members located at the distal end of the elongate shaft and supporting first and second electrodes, respectively, the jaw members being relatively spaced from one another in an open position in which the first and second electrodes are spaced from one another; and a closed position in which the first electrode is located adjacent to the second electrode, are movable; a power cable having a pair of electrically conductive elements and a first end to which it is connected to a source of high frequency electromagnetic energy and a second end to which it is connected to the first and second electrodes; and a first capacitive element located in the instrument and connected in series between a first of the pair of electrically conductive elements of the cable and the first electrode. Bipolar electrosurgical element after Claim 1 further comprising a second capacitive element located in the instrument and connected in series between a second of the pair of electrically conductive elements of the cable and the second electrode. Bipolar electrosurgical instrument after Claim 1 or 2 wherein the first electrode is an active electrode and the second electrode is a counter electrode. Bipolar electrosurgical instrument after Claim 1 or 2 wherein the first electrode is a counter electrode and the second electrode is an active electrode. A bipolar electrosurgical instrument as claimed in any one of the preceding claims, wherein the or each capacitive element is a capacitor. The bipolar electrosurgical instrument of any one of the preceding claims, further comprising a control cable including at least one control conductor for providing a control signal path. Bipolar electrosurgical instrument according to one of the preceding claims, further comprising a measuring cable, which comprises at least one measuring conductor for providing a measurement signal path. An electrosurgical system comprising a bipolar electrosurgical instrument as claimed in any one of the preceding claims and a waveform generator connected to the power cord of the instrument for providing high frequency signals to the first and second electrodes via the power cable. Electrosurgical system after Claim 8 wherein the waveform generator comprises a radio frequency signal generator for providing a radio frequency signal to the first and second electrodes via the power cable and a controller for controlling the operation of the radio frequency signal generator in response to a received control input.

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